JP2004097602A - Puncture apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To smoothly and safely perform operation for collecting a body liquid by puncture to the skin by a puncture means and suction by a manual pressure reducing means in order. <P>SOLUTION: This puncture apparatus reduces pressure within a puncture opening part 9 by a manual pump 55 in the state of clogging the opening part 9 with a finger tip, shoots a lancet 5 into the opening part 9 by a puncture mechanism 11 to make an injure at the finger tip, or the like , and sucks and collects the body liquid by utilizing pressure-reduced suction force by the manual pump 55. When a pressure reduced value in the case of reducing the pressure in the opening part 9 by the pump 55 becomes an optimal value, this is detected by a pressure sensor 79 and information on this is given by an informing means such as a buzzer. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a technique of a puncture device capable of measuring a component such as a blood glucose level in a collected body fluid at the same time as collecting a required amount of a body fluid when performing a clinical test or the like of a body fluid such as blood. Belongs to the field.
[0002]
[Prior art]
Conventionally, in order to measure various components in blood, a method of measuring a reaction product of specific oxygen that reacts with a specific component in blood has been studied. In particular, blood glucose measurement is important for monitoring the condition of a patient, and self-blood glucose measurement, in which the patient monitors daily fluctuations in blood glucose, has been recommended. In recent years, the number of diabetic patients has been increasing, and a simple and painless measurement method and measurement means have been demanded. The measurement of the blood glucose level is often performed using a reaction in which glucose such as glucose oxidase or glucose dehydrogenase oxidizes glucose. At present, a test paper that develops a color according to the amount of glucose in blood is mounted, blood is supplied to the test paper, developed and colored, and the degree of the color is measured optically (colorimetrically). It is performed using a blood glucose measuring device such as a colorimetric method for quantifying a blood glucose level, an electrode type method for electrically measuring the product of the oxygen reaction, and the like (for example, Patent Document 1, Patent Document 1). 2).
In these measurement methods, it is essential to collect blood for measurement. In these methods, a puncture device called a lancet is used to form a wound on the skin of a patient's fingertip or the like by using a puncturing device called a lancet to exude body fluid such as blood, and then use the puncture device. Is transferred to a separately prepared test paper or an electrode piece on which a sensor is printed, and measured by a blood glucose measuring device. Prior to these measurements, the patient punctures with a puncture needle to collect his or her own blood for measurement, and then presses around the puncture site with a finger or the like, or squeezes out the blood by heating, decompression, etc. Is being done.
Further, in recent years, a component collection tool in which a puncture tool having a puncture needle for obtaining blood from the skin and the test paper described above have been developed has been developed. Integrating such a puncture device and a test strip can simplify the operation without separately mounting the puncture device and the sensor on the blood glucose measuring device, and can greatly improve the usability (for example, , Patent Document 3, Patent Document 4).
[0003]
[Patent Document 1]
JP-A-11-183474
[Patent Document 2]
JP-A-60-17344
[Patent Document 3]
JP-A-61-286738
[Patent Document 4]
JP 2001-524343 A
[0004]
[Problems to be solved by the invention]
However, a bodily fluid component measuring device that integrates a puncturing mechanism for puncturing a puncture needle and a measuring mechanism for measuring a component concentration with a test strip, an electrode sensor, and the like, and further combines a decompression pump driving device for reducing the pressure around the punctured site. Is large and easy to carry
Very inconvenient.
One solution to downsizing the device is to not use an electrically operated vacuum pump drive. By employing a pressure reducing mechanism that functions manually, the required power is very small, and there is no need to incorporate an electric mechanism, so that a reduction in size and weight can be achieved.
However, when a body fluid such as blood is sucked from a fingertip or the like using a decompression means such as a manual pump, it is unknown how long the decompression operation can be continued, and if the suction is weak, it is not possible to measure a component of the body fluid. Sufficient, especially if the suction force is too strong, the body fluid will be scattered, causing inconvenience in the component detection procedure of the body fluid, causing internal bleeding at the fingertip etc., and causing pain to the patient. There is a possibility that a problem such as an accident may occur.
[0005]
The present invention has been made in order to solve the above-described problem, and it is intended to smoothly and safely perform an operation of piercing skin by a puncturing means and exuding a bodily fluid by suction by a manual pressure reducing means. It is an object of the present invention to provide a puncture device that can perform the puncturing.
[0006]
[Means for Solving the Problems]
Claim 1 of the puncture device of the present invention for achieving the above object is a puncture mechanism that emits puncture means for forming a wound on the skin and exuding bodily fluids into the puncture opening; The apparatus comprises a manual pressure reducing means for manually reducing the pressure, and a notifying means for notifying that at least the reduced pressure value in the puncturing opening by the manual pressure reducing means has reached a predetermined value.
A puncturing apparatus according to claim 2 which is dependent on claim 1 of the present invention is provided with an atmosphere opening means for opening the inside of the puncturing opening depressurized by the manual pressure reducing means to the atmosphere as necessary.
A puncturing apparatus according to claim 3 which is dependent on claim 2 of the present invention, wherein the puncturing mechanism has a firing means for firing the puncturing means into the puncturing opening, and the firing means also serves as the atmosphere opening means. It is a thing.
The puncturing apparatus according to claim 4 which is dependent on claim 1 of the present invention, wherein the puncturing means emits the puncturing means to the puncturing opening to form a wound on the skin, thereby exuding the bodily fluid component into the puncturing opening. Is provided.
A puncturing apparatus according to claim 5 which is dependent on claim 1 of the present invention is provided with a monitor for displaying a reduced pressure state in the puncturing opening by the manual pressure reducing means.
A puncturing apparatus according to claim 6 which is dependent on claim 1 of the present invention has a puncturing opening in which a puncturing mechanism for emitting a puncturing means and forming a wound on the skin is housed in the puncturing opening. A second case accommodating one case and a manual decompression unit for decompressing the inside of the puncturing opening, wherein the second case for operating the manual decompression unit by sliding with respect to the first case; A case, and a monitor provided in the second case, the monitor displaying at least a pressure reduction state in the puncturing opening by the manual pressure reduction means.
[0007]
Claim 1 of the puncture device of the present invention configured as described above, for example, in the state where the puncture means is pressed and closed with a fingertip or the like against the puncture opening from which the puncture means is fired, operating the manual decompression means, A method of sucking and collecting body fluid by evacuating the inside of the puncturing opening in advance and then firing the puncturing means into the puncturing opening and scratching the fingertip, etc., and a puncturing method in which the puncturing means is fired In a state where the fingertip or the like is pressed against the opening for closing, the puncturing means is fired into the puncturing opening to damage the fingertip or the like, and thereafter, the manual decompression means is operated to operate the puncturing opening. By depressurizing the inside of the unit, it is possible to use two kinds of methods, a method of sucking and collecting body fluid.
In any method, the pressure inside the puncture opening is reduced by the manual evacuating means, and when the body fluid is sucked and collected from the wound part formed on the fingertip or the like by the puncturing means, the pressure inside the puncturing opening is reduced. The user can be notified that the value has reached the predetermined value by a notification means such as a buzzer. Thereby, the user can easily know that the inside of the puncturing opening has at least been in a decompressed state that is optimal for suctioning and collecting body fluid.
A second aspect of the puncture apparatus according to the present invention is such that the inside of the puncture opening, which is depressurized by the manual decompression means, can be released to the atmosphere as needed by the atmosphere release means. .
A third aspect of the puncture apparatus according to the present invention is a launching means for launching the puncturing means into the puncturing opening, which also serves as the atmosphere opening means.
The puncture device according to the present invention is characterized in that the puncture device is fired into the puncture opening to form a wound on a fingertip or the like and the component of the bodily fluid exuded is immediately detected by the component detection device. It can be detected and measured.
The puncture device according to the present invention can be displayed on a monitor in a state where the pressure in the puncture opening is reduced by the manual pressure reducing means.
A puncturing apparatus according to the present invention is configured such that a puncturing mechanism is housed in a first case having a puncturing opening formed therein, and puncturing means of the puncturing mechanism is fired into the puncturing opening. Then, a manual decompression unit is accommodated in a second case that is slid with respect to the first case, and the manual decompression unit depressurizes the inside of the puncturing opening of the first case by sliding with respect to the first case. Thus, at least the decompression state in the puncturing opening depressurized by the manual decompression means is displayed on a monitor provided in the second case.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of a puncture device to which the present invention is applied will be described with reference to the drawings.
First, as shown in FIGS. 1 to 5, this puncture device 1 is a cylindrical second molded product made of a molded component (a synthetic resin molded product, hereinafter simply referred to as a molded component). One case 2 and a second case 3 having a rectangular parallelepiped shape are provided. The second case 3 is slidable in the axial direction on the outer periphery of the front and rear end portions of the first case 2 by a pair of sliding portions 3a and 3b formed at the front and rear end portions thereof by cylindrical integral molding or the like. Has been inserted. Therefore, the second case 3 is configured to be slidable relative to the first case 2 in the directions of arrows a and b, which are the axial directions of the first case 2, at a fixed stroke S1 shown in FIG. The second case 3 has a rectangular monitor 4 shown in FIG. 1 embedded therein. As shown in FIG. 3 and the like, the liquid crystal display panel 5 and the A circuit board 6 on which a control circuit described later is mounted is incorporated.
[0009]
The first case 2 is formed of a cylindrical tip cap 201, a front cylindrical portion 202, an intermediate cylindrical portion 203, a rear cylindrical portion 204, and the like, which are both formed by molded parts and concentrically connected. ing. The tip cap 201 is detachably attached to the outer periphery of the front end portion of the front side cylindrical portion 202 through the screw fitting portion 8 and is mounted concentrically, and the tip of the tip cap 201 has a circular or similar puncturing opening. 9 is open. The tip cap 201 is formed transparent so that the inside of the puncturing opening 9 can be seen through from the outside. Further, the intermediate cylindrical portion 203 disposed between the front cylindrical portion 202 and the rear cylindrical portion 204 is configured as a rotation adjusting cylinder capable of adjusting the rotation around the axis.
[0010]
Next, puncturing mechanism 11 housed in first case 2 of puncturing apparatus 1 will be described with reference to FIGS.
First, a component sampling tool (hereinafter, referred to as a chip) 12 having a puncturing means and a component detecting means is used for the puncturing mechanism 11. The tip 12 is formed of a molded part or the like, and a lancet 13 serving as a puncturing means is housed at a central position inside. The lancet 13 is formed in a small-diameter cylindrical shape, and a puncture needle 14 is embedded concentrically at the center on the tip 13a side.
Inside the tip 12a of the chip 12, a component detector 15 composed of a pair of electrodes, which is a component detector for detecting a body fluid such as blood, is housed. Are buried in parallel. The rear ends of the pair of electrode terminals 16 are exposed in a pair of terminal holes 17 which are small windows formed on the upper surface of the chip 12.
[0011]
A tip mounting portion 20 which is a component collecting tool mounting portion in which the rear end 12b side of the chip 12 is detachably mounted in the direction of arrow b inside the front end of the front cylindrical portion 202 at the front end of the first case 2 is integrally formed. Have been. The mounting of the chip 12 into the chip mounting portion 20 is performed with the tip cap 201 removed from the front cylindrical portion 202, and after the mounting of the chip 12 into the chip mounting portion 20 in the direction of arrow b. The tip 12 is fixed by detachably attaching the tip cap 201 to the outer periphery of the tip of the front cylindrical portion 202.
A pair of left and right connection electrodes 21 is buried in the front cylindrical portion 202 above the chip mounting portion 20 in parallel. Then, when the rear end 12b side of the chip 12 is detachably inserted into the chip mounting portion 20 and fixed by the front end cap 201, the crimp terminal 21a which is the front end of the pair of left and right connection electrodes 21 It is connected (crimped) to a pair of left and right electrode terminals 16 exposed in a pair of left and right terminal holes 17 on the upper surface. As a result, the component detection unit 15 is mounted on the circuit board 6 via the pair of left and right electrode terminals 16 and the connection electrodes 21, and is configured to be electrically connected to a control circuit 81 described later.
[0012]
Next, a cylindrical puncturing shaft 23 is concentrically arranged in the front cylindrical portion 202, and a tip portion 23a of the puncturing shaft 23 is formed, for example, in a substantially C-shape in a cross-sectional shape. The rear end 13b of the lancet 13 described above is configured as a lancet mounting portion into which the rear end 13b of the lancet 13 is detachably inserted (mounted) by a light press-fitting method. Then, puncturing mechanism 11 is configured to drive puncturing shaft 23 in the directions of arrows a and b between standby position P1 and puncturing position P2. The puncture mechanism 11 includes a firing spring 25 composed of a compression coil spring or the like for firing the puncture shaft 23 from the standby position P1 shown in FIGS. 2 to 4 to the puncture position P2 shown in FIGS. And a rebound spring 26 composed of a compression coil spring or the like that immediately retracts the puncture shaft 23 immediately after the firing from the puncture position P2 shown in FIG. 8 to the intermediate position P3 shown in FIG. At this time, the firing spring 25 is inserted around the outer periphery of the small cylindrical portion 27 concentrically integrally formed inside the rear end of the front cylindrical portion 202, and is integrally formed on the outer periphery of the puncture shaft 23 by molding. The formed spring contact flange portion 28 is configured to be pressed in the direction of arrow a. The rebound spring 26 is inserted on the outer periphery of the rear end 23b of the puncture shaft 23 on the side of the arrow b from the small cylindrical portion 27, and is fixed concentrically to the rear end 23b by screwing or the like. The stop flange portion 29 is configured to be pressed in the direction of arrow b.
[0013]
The puncturing mechanism 11 includes a locking mechanism 32 that locks the puncturing shaft 23 at the standby position P1 at the time of mounting a chip, which will be described later. The locking mechanism 32 includes a pair of symmetrically-shaped elastic locking arms 33 integrally formed at a position opposite to the rear end of the front cylindrical portion 202 by 180 ° and extended in the direction of arrow b. The tip 33a side of the elastic locking arm 33 is symmetrically inclined so as to approach each other as it proceeds in the direction of arrow b. Note that an elastic biasing force in the direction of the arrow c which is the inner direction is applied to the pair of elastic locking arms 33 in advance. In addition, a pair of symmetrical locking claws 34 are formed by integral molding or the like at substantially inner middle positions in the longitudinal direction of the pair of elastic locking arms 33 facing each other. When the puncture shaft 23 is pushed back in the direction of arrow b against the firing spring 25 from the intermediate position P3 to the standby position P1, the locking flange portion 29 causes the pair of elastic locking arms 33 to face outward. The pair of locking claws 34 are pushed over in the direction of arrow b while being pushed and spread against the elasticity in the direction of arrow d. At the moment when the locking flange portion 29 crosses over the pair of locking claws 34 in the direction of arrow b, the pair of elastic locking arms 33 automatically closes in the direction of arrow c, and the locking flange portion 29 is closed. Both sides are configured to be locked by a pair of locking claws 34.
[0014]
An operating shaft 37 is concentrically accommodated in the rear cylindrical portion 204 and is movably accommodated in the directions of arrows a and b. The operating shaft 37 is concentrically fixed to the rear end of the operating shaft 37 by a screw or the like. The operation button 38 serving as a firing unit and an atmosphere release unit protrudes rearward of the rear cylindrical part 204. A conical cam portion 39 is formed at the front end of the operation shaft 37, and the operation shaft 37 and the operation button 38 are moved in the direction of the arrow b with respect to the rear cylindrical portion 204 by a return spring 40 composed of a compression coil spring or the like. The operation shaft 37 and the operation button 38 are fixed at a fixed position by a pair of protrusions 41 integrally formed on the outer periphery of the front end of the operation button 38 and the like being brought into contact with the stopper portion 45 in the direction of arrow b. It is configured to be stopped.
As shown in FIG. 2, a pair of front and rear sliding portions 3a, 3b of the second case 3 are supported by the outer periphery of the tip cap 201 and the outer periphery of the operation button 38, and the arrow a, It is configured to be slidable in the direction b.
[0015]
Next, the puncturing mechanism 11 is provided with a puncturing depth adjusting mechanism 44, and the puncturing depth adjusting mechanism 44 is disposed in the intermediate cylindrical portion 203. The puncturing depth adjusting mechanism 44 will be described later. When the puncture is performed, the amount of protrusion of the distal end 14a of the puncture needle 14 from the distal end cap 20 is adjusted. This is performed by adjusting the stop position of the flange portion 29.
As described above, the intermediate cylindrical portion 203 is configured as a rotation adjusting cylinder, and a pair of cylindrical step portions facing the direction of arrow b is provided on the inner peripheral portion near the front end of the intermediate cylindrical portion 203. Is formed. The pair of stepped stopper portions 45 are formed stepwise in the directions of the arrows a and b as they proceed in the circumferential direction. On the other hand, a pair of projections 46 are integrally formed at two places orthogonal to the pair of elastic arms 23 on the outer periphery of the locking flange 29 concentrically fixed to the rear end 23 b of the puncture shaft 23. ing.
When the puncture shaft 23 is fired from the standby position P1 to the puncture position P2 in the direction of the arrow a by the firing spring 25 at the time of puncturing, which will be described later, the pair of small projections 46 is provided at two places of the pair of step-like stopper portions 45. The puncture shaft 23 is configured to be stopped by a collision. Then, by adjusting the rotation of the intermediate cylindrical portion 203 around the axis, the circumferential phase of the pair of step-like stopper portions 45 can be adjusted, and the collision of the pair of small protrusions 46 in the direction of arrow a can be performed. The stop position can be finely adjusted. The fine adjustment is configured so that the puncture depth of the distal end 14a of the puncture needle 14 is finely adjusted.
[0016]
A large number of concave grooves 47 are formed in the outer periphery of the intermediate cylindrical portion 203 in parallel with the axis, and are formed integrally with the outer periphery of the rear end of the front cylindrical portion 202 and the outer periphery of the front end of the rear cylindrical portion 204. A single positioning pin 49 is provided between the pair of front and rear flange portions 48 formed in parallel with the intermediate cylindrical portion 203. Both ends of the positioning pin 49 are slidably held in a pair of elongated holes 50 formed in the pair of flange portions 48 and extending in the radial direction. A positioning pin 49 is selectively engaged in one concave groove 47 on the outer periphery of the intermediate cylindrical portion 203 from the direction of arrow e.
Further, a window hole 52 is opened at a position corresponding to a lower portion of the intermediate cylindrical portion 203 at the bottom of the second case 3, and a finger is inserted into the window hole 52 to adjust the rotation of the intermediate cylindrical portion 203. While the positioning pin 49 moves in parallel in the directions of arrows e and f against the pressing spring 51, the positioning pin 49 gets over the concave groove 47 on the outer periphery of the intermediate cylindrical portion 203 one by one, so that the intermediate cylindrical portion 203 is fixed. It is configured to click and position at each angle.
[0017]
Next, the handling operation of the puncture device 1 configured as described above will be described.
First, when the tip 12 is mounted, the puncture shaft 23 is located at the intermediate position P3 shown in FIG. However, when the tip is mounted, the operation button 38 and the operation shaft 37 are shown by solid lines in FIGS. 2 and 3 and are returned in the direction of arrow b by a return spring 40 to a home position P5 shown by a dashed line in FIG. The pair of elastic locking arms 33 of the locking mechanism 32 are shown by solid lines in FIG. 4 and closed in the direction of arrow e as shown by dashed lines in FIG.
[0018]
Then, after the tip cap 201 is detached from the screw fitting portion 8, the rear end 12 b of the tip 2 is removably inserted into the tip mounting portion 20 at the front end of the front end cylindrical portion 202 from the direction of arrow b, and the lancet A rear end 13b of the puncture shaft 13 is detachably attached to a front end 23a of the puncture shaft 23 from the direction of arrow b. At this time, the lancet 13 pushes the puncture shaft 23 back from the intermediate position P3 shown in FIG. 9 to the standby position P1 shown in FIG. While the force is charged, both sides of the locking flange portion 29 are locked by the pair of locking claws 34 of the pair of elastic locking arms 33 of the locking mechanism 32, and the puncture shaft 23 is locked at the standby position P1. Is done.
Then, after that, as shown in FIG. 4, when the tip cap 201 is mounted on the screw fitting portion 8 on the outer periphery of the front cylindrical portion 202 and tightened, the chip 12 is completely fixed in the chip mounting portion 20, and the chip The component detection unit 15 at the tip of the tip 12 is arranged close to one side in the puncturing opening 9 at the tip of the tip 12, and the tip mounting is completed.
[0019]
Next, after the tip mounting is completed, the operation button 38 is lightly pressed by a finger in the direction of arrow a against the return spring 40 from the fixed position P5 shown by the dashed line in FIGS. 6 and 7 to the firing position P6 shown by the solid line. As shown in FIG. 8, the cam portion 39 on the outer periphery of the distal end of the operating shaft 37 is inserted from the direction of the arrow a into the space between the distal ends 33a of the pair of elastic locking arms 33 of the locking mechanism 32. The distal end 33a of the elastic locking arm 33 is pushed out in the direction of arrow d. Then, the locked state of the locking flange 29 by the pair of locking claws 34 is released, and at that moment, the spring force charged in the firing spring 25 causes the spring abutting spring abutting flange portion 28. Is pushed in the direction of the arrow a, and the puncture shaft 23 is pushed out in the direction of the arrow a from the standby position P1 to the puncture position P2.
Then, the lancet 13 in the tip 12 is pushed out integrally with the puncture shaft 23 in the direction of the arrow a, and the puncture needle 14 integral with the lancet 13 is pushed out in the direction of the arrow a. Through the substantially central portion of the puncturing opening 9, and protrudes out of the distal end cap 201.
At this time, as shown in FIG. 11, an annular small projection 38a integrally formed on the outer periphery of the operation button 38 contacts an annular small projection 3d integrally formed on the inner periphery of the sliding portion 3b of the second case 3. Touched and stopped. When the finger is released from the operation button 38, the operation button 38 and the operation shaft 37 are integrally pushed back to the home position P5 by the return spring 40.
[0020]
On the other hand, the firing spring 25 is opened immediately after pushing the puncture shaft 23 from the standby position P1 in the direction of the arrow a, and the puncture shaft 23 reaches the puncture position P2 by inertia and gravity in the direction of the arrow a. . On the other hand, immediately before the puncture shaft 23 reaches the puncture position P2, the spring force is charged to the rebound spring 26.
Accordingly, immediately after the distal end 14a of the puncture needle 14 projects outside the distal end cap 201, the puncture shaft 23 is moved from the puncture position P2 to the intermediate position P3 by the spring force of the rebound spring 26, as shown in FIG. The tip 14a of the puncture needle 14 is quickly pulled back into the tip cap 201 in the direction of arrow b.
[0021]
Next, the manual pump 55 which is a manual decompression unit housed in the second case 3 will be described with reference to FIGS.
The manual pump 55 is disposed in parallel on one side of the first case 2 and includes a cylinder 56 and a piston 57 formed of a molded component, metal, or the like. Then, the cylinder 56 is fixed in the second case 3 by the cylinder fixing portion 59, and the piston 57 is fixed to the one side portion of the rear cylindrical portion 204 of the first case 2 so as to be integrally formed at right angles into the piston fixing portion 60. Fixed. A compression coil spring or the like is provided between a spring support portion 61 fixed inside the rear side wall 3c of the second case 3 and a spring support portion 62 formed integrally with the rear side of the piston fixing portion 60. A return spring 63 is mounted concentrically with the piston 57.
Therefore, the manual pump 55 moves the second case 3 with respect to the first case 2 between the fixed position P9 shown by the dashed line in FIG. 5 and the sliding position P10 shown by the solid line in the return spring 63. By reciprocating in the directions of arrows a and b in opposition, the piston 57 is reciprocated in the directions of arrows a and b in the decompression chamber 65 of the cylinder 56. A pair of check valves 65 and 66, which are automatic opening / closing valves for a central portion of the distal end of the piston 57 and a central portion of the distal end of the cylinder 56, are provided so as to sandwich the pressure reducing chamber 64 in the cylinder 56. A sealing ring 67 such as an O-ring is fitted around the outer periphery of the distal end of the piston 57.
[0022]
Then, a decompression chamber 64 in the cylinder 56 is provided with air protruding from the side surface of the rear cylindrical portion 204 of the first case 2 via an air suction passage 69 formed along the center of the piston 57 and a T-shaped pipe joint 70. The air suction port 71 is connected to a part of an air suction groove 72 formed in a cylindrical shape on the inner periphery of the front end side of the rear cylindrical portion 204 at a right angle. A plurality of air suction grooves 73 formed in a straight line parallel to the axis at regular intervals on the outer circumference of the front end side of the operation shaft 37 of the puncture mechanism 11 are provided inside the cylindrical air suction groove 72. The first ends of the air suction grooves 72 and 73 are open to the inside of the intermediate cylindrical portion 203 of the first case 2.
[0023]
In order to make the range from the puncturing opening 9 of the first case 2 to the inside of the rear cylindrical portion 204 airtight, an O-ring or the like is provided between the tip cap 201 and the outer periphery of the front end of the front cylindrical portion 202. A sealing packing 74 is incorporated, and a pair of bellows or the like is provided between the rear end of the front cylindrical portion 202 and the front end of the intermediate cylindrical portion 203 and between the rear end of the intermediate cylindrical portion 203 and the front end of the rear cylindrical portion 204. Sealing packings 75 and 76 are incorporated. Further, a sealing slide packing 77 such as an O-ring incorporated into the outer periphery of the intermediate portion of the operation shaft 37 is slidably movable in the directions of arrows a and b in a state of being pressed against the inner periphery of the rear cylindrical portion 204. ing.
The pressure sensor 79 is connected to the remaining one of the three connection ports of the T-shaped pipe joint 70.
[0024]
This manual pump 55 is configured as described above, and can be operated as follows.
That is, as shown in FIG. 4, in a state where the puncture opening 9 of the distal end cap 201 is closed with the fingertip F or the like, as shown in FIG. When the case 3 is slid in the direction of the arrow a against the first case 2 from the fixed position P9 shown by the dashed line to the sliding position P10 shown by the solid line by the stroke S1 against the return spring 61, the manual pump 55 The cylinder 56 is slid with respect to the piston 57 in the direction of arrow a. At this time, while the check valve 66 of the cylinder 56 is closed, the volume of the pressure reducing chamber 64 is expanded, and the pressure in the pressure reducing chamber 64 is reduced (negative pressure).
[0025]
Then, the check valve 65 of the piston 57 opens, and an air suction force is applied to the air suction port 71 of the first case 2 via the air suction passage 69 in the piston 57 and the T-shaped pipe joint 70, and FIG. As shown in FIG. 10, air in the puncturing opening 9 at the tip of the first case 2 is sucked in the direction of arrow g through gaps between the respective parts of the puncturing mechanism 11 in the first case 2, and From the plurality of air suction grooves on the outer circumference, the air flows into the air suction port 71 through the cylindrical air suction groove 72 on the inner circumference of the rear cylindrical portion 204, and as shown in FIG. The air flows into the decompression chamber 64 through the joint 70, the air suction passage 69 and the check valve 65.
Then, with the hand separated from the second case 3, the second case 3 is returned from the first case 2 by a return spring 63 from a sliding position P10 shown by a solid line in FIG. When pushed back in the direction b, the cylinder 56 of the manual pump 55 is slid with respect to the piston 57 in the direction of the arrow b. At this time, while the check valve 65 of the piston 57 is closed, the volume of the pressure reducing chamber 64 is reduced, and the air in the pressure reducing chamber 64 pushes the check valve 66 of the cylinder 56 open and is discharged to the outside.
[0026]
Accordingly, by repeatedly reciprocating the second case 3 in the directions of the arrows a and b with respect to the first case 2 while simultaneously using the spring force of the return spring 63, the piston 57 with respect to the cylinder 56 in the directions of the arrows a and b is moved. A pumping operation can be performed, whereby the pressure in the puncturing opening 9 at the distal end in the first case 2 can be reduced (negative pressure).
Then, the pressure reduction state in the puncturing opening 9 is detected by the pressure sensor 79 connected to the T-shaped pipe joint 70 and displayed on the monitor 4. When the inside of the puncture opening 9 decompressed in this way is opened to the atmosphere, the operation button 38 which is also used as the firing means and the atmosphere opening means is pressed slightly with a finger, and the operation button 38 is operated. The shaft 37 is integrated with the return spring 40 from the home position P5 shown in FIGS. 2, 3 and 12 to the open-to-atmosphere position P7 shown in FIGS. 6 and 12 via the firing position P6 shown in FIGS. Push in the direction of arrow a against it. At this time, as shown in FIG. 12, an annular small projection 38a integrally formed on the outer periphery of the operation button 38 is formed around the sliding portion 3b of the second case 3 at an interval. Of the projection 3d and the large annular projection 3e, the inside of the small annular projection 3d is clicked and clicked, and is stopped by being brought into contact with the large annular projection 3e.
[0027]
When the operation shaft 37 is pushed to the atmosphere release position P7, the sealing slide packing 77 fitted on the outer periphery of the operation shaft 37 is formed on the inner periphery of the rear cylindrical portion 204 as shown in FIG. The rear end 72a of the air suction groove 72 is slid from the rear end 72a of the formed cylindrical air suction groove 72 in the direction of arrow a to the position deviated by the stroke S2, and the rear end 72a of the air suction groove 72 is opened to the atmosphere. .
Then, at that moment, the air flows from the rear end 72a of the cylindrical air suction groove 72 into the first case 2 in the direction of arrow h, and the inside of the puncturing opening 9 at the front end in the first case 2 becomes large. It is returned to atmospheric pressure. After that, if the finger is released from the operation button 38, the operation button 38 and the operation shaft 37 are integrally pushed back to the home position P5 by the return spring 40.
[0028]
Here, the puncture device 1 operated as described above is used to injure skin such as a fingertip and collect body fluid such as blood, and at the same time, measure components such as blood glucose level in the collected body fluid. A series of operations to be performed will be described.
First, as shown in FIG. 4, the puncture opening 9 at the tip of the tip cap 201 of the first case 2 is lightly closed with a fingertip F or the like.
Then, as shown in FIG. 5, the second case 3 is reciprocated by a stroke S1 in the directions of arrows a and b with respect to the first case 2 to perform the pumping operation of the manual pump 55.
Then, as shown in FIG. 4, the pressure in the puncturing opening 9 is reduced, and a suction force in the direction of arrow g is applied to the skin such as the fingertip F.
[0029]
Then, when the operation button 38 is pushed in the direction of the arrow a from the home position shown in FIG. 3 to the firing position P6 shown in FIG. 6, the locking mechanism 32 of the puncture mechanism 11 locks the standby position P1 as shown in FIG. The locked state of the puncture shaft 23 is released by the operation shaft 37.
Then, the puncture shaft 23 is fired by the firing spring 25 in the direction of the arrow a from the standby position P1 to the puncture position P2, and the tip 14a of the puncture needle 14 of the lancet 13 is punctured at the fingertip F or the like, and the fingertip F is damaged. To form
Immediately after this puncture, the puncture shaft 23 is pulled back from the puncture position P2 to the intermediate position P3 by the rebound spring 26 in the direction of arrow b, and the tip 14a of the puncture needle 14 is immediately removed from the fingertip F or the like in the direction of arrow b. It is.
[0030]
Then, immediately after the tip 14a of the puncture needle 14 is withdrawn in the direction of the arrow b, the body fluid f such as blood is forcibly exuded from the wound portion such as the fingertip F by the reduced pressure suction force in the puncture opening 9. Will be.
The exuded bodily fluid f is attached to the component detection unit 15 disposed in the puncturing opening 9, and an electric signal from the component detection unit 15 is passed through the electrode terminal 16 and the connection electrode 21 to the circuit board 6. Is sent to a control circuit 81, which will be described later, which is mounted on the device, and the component of the body fluid f is immediately measured.
Then, by pushing the operation button 38 from the home position P5 shown in FIG. 12 to the atmosphere release position P7 in the direction of arrow b to open the inside of the puncture opening 9 to the atmosphere, the fingertip F or the like can be easily removed from the tip cap 201. Can be pulled apart.
[0031]
According to the puncturing apparatus 1, with the puncturing opening 9 lightly closed with the fingertip F or the like, the operation button 38 is pushed from the home position P5 to the firing position P6, and the puncture mechanism 11 causes the tip 14a of the puncture needle 14 to be released. Is punctured into the fingertip F or the like from the direction of the arrow a to scratch the fingertip F or the like, and then the pumping operation of the manual pump 55 is performed to decompress the inside of the puncture opening 9 and to use the reduced-pressure suction force. For example, by forcibly exuding a body fluid f such as blood from a wound portion such as a fingertip F, the component detecting unit 15 can detect the body fluid f.
[0032]
Next, a control method of the puncture device 1 will be described with reference to FIG.
The control circuit 81 mounted on the circuit board 6 of the puncture device 1 has a processing unit 82 constituted by a microcomputer (CPU). The component detecting section 15 is connected to the processing section 82 through a component measuring section 83. Further, a pressure sensor 79 for detecting a pressure reduction state in the puncture opening 9 by the manual pump 55 is connected to the processing unit 82 through a pressure reduction value measurement unit 84. The processing unit 82 includes a pressure reduction notification unit 85, a power supply unit 86 such as a battery, an operation unit 87 as various switches, a temperature detection unit 88, an oscillation unit 89, a power supply voltage detection unit 90, a data storage unit 91, A clock unit 92 and the like are connected. The processing unit 82 is connected to the monitor 4 as a display unit, a buzzer output unit 93 as one of alarm means, and the like.
[0033]
As described above, when the puncture opening 9 is closed by the fingertip F and the inside of the puncture opening 9 is depressurized by the pumping operation of the manual pump 55, the pressure in the puncture opening 9 is reduced. The value is detected by the pressure sensor 79, and the reduced pressure value is measured by the reduced pressure value measuring unit 84.
Then, the measured value measured by the reduced pressure value measuring section 84 is sent from the processing section 82 to the reduced pressure notifying section 85, and it is determined whether or not the measured value has reached a predetermined value set in advance. 85. Then, when the pressure reduction value in the puncturing opening 9 reaches a value which is a predetermined value which is optimal for aspiration and collection of body fluid, an information signal is output from the pressure reduction notification unit 85 to the processing unit 82. The processing unit 82 drives the buzzer output unit 93 as one notification unit, and performs notification to output a blink signal or the like on the monitor 4 as notification and / or another notification unit.
[0034]
Therefore, the user (patient) of the puncture device 1 can hear and / or hear that the inside of the puncture opening 9 has become optimal for aspiration and collection of bodily fluid by notification by a notification means such as a buzzer output and a blinking signal. At that point, the manual pump 55 can be safely stopped. Then, the user can safely aspirate and collect body fluid.
As a result, since the decompression value in the puncture opening 9 inadvertently exceeds the risk value, internal bleeding may occur on the skin of the finger or the like, or blood or the like may be generated from the wound portion attached to the fingertip or the like by the puncture needle 14. As a result, the inconvenience that the component detecting unit 15 cannot detect the component of the body fluid as a result of the body fluid being strongly sucked out and scattered by the strong suction power can be prevented.
The puncture needle 14 is pierced into a fingertip or the like to form a wound, and a body fluid such as blood, which is forcibly sucked and collected from the wound by the reduced-pressure suction force in the puncturing opening 9, is safely detected by the component detection unit 15. In addition, the component is reliably detected and measured by the component measuring unit 83, and the component data is output to the processing unit 82. Then, the processing unit 82 stores the data in the data storage unit 91 and displays the component data on the monitor 4.
[0035]
The embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various modifications can be made based on the technical idea of the present invention.
[0036]
【The invention's effect】
The puncture device of the present invention configured as described above has the following effects.
[0037]
Claim 1 is that the pressure in the puncture opening is reduced by manual decompression means, and when the body fluid is sucked and collected from a wound part formed on a fingertip or the like by the puncture means, the reduced pressure value in the puncture opening is: Since the user can be notified of the predetermined value by a notification means such as a buzzer, it is possible for the user to know at least that the decompression state is optimal for aspiration and collection of body fluid. The end of the decompression operation by the manual decompression means can be easily recognized, and the user performs an excessive decompression operation by mistake, causing internal bleeding at the fingertips or the like, and aspirated and collected bodily fluids are scattered. As a result, inconvenience such as failure to collect the body fluid can be prevented beforehand, and operability and safety can be significantly improved.
[0038]
According to the second aspect of the present invention, the inside of the puncturing opening, which is depressurized by the manual decompression means, can be released to the atmosphere as needed by the air release means. Operability and safety are improved.
[0039]
A third aspect of the present invention is a launching means for launching the puncturing means into the puncturing opening, which also serves as the atmosphere opening means, so that the configuration can be simplified.
[0040]
According to the fourth aspect of the present invention, the component of the bodily fluid that has been exuded by firing the puncturing means into the puncturing opening to form a wound on the fingertip or the like can be immediately detected and measured by the component detecting means. With this configuration, the components of the collected body fluid can be detected simultaneously with the suction and collection of the body fluid.
[0041]
According to claim 5 which depends on claim 1, since the decompression state in the puncturing opening which is decompressed by the manual decompression means can be displayed on the monitor, the user can set the decompression value in the puncturing opening to an optimum value. It can be easily and visually recognized that this has happened.
[0042]
The puncturing mechanism is housed in a first case having a puncturing opening formed therein, and puncturing means of the puncturing mechanism is fired into the puncturing opening. A manual decompression unit is accommodated in the second case to be slid, and the manual decompression unit is configured to depressurize the inside of the puncturing opening of the first case by sliding with respect to the first case. The decompression state in the puncturing opening, which is decompressed by the puncturing opening, is displayed on the monitor provided in the second case, so that the second case provided with the monitor slides on the first case provided with the puncturing mechanism. By moving, the pumping operation of the manual pressure reducing means can be performed, the pressure inside the puncturing opening can be easily reduced, and a operable puncturing apparatus can be provided.
[Brief description of the drawings]
FIG. 1 is a front view of a puncture device to which the present invention is applied.
FIG. 2 is a partially cutaway front view of the puncture device according to the first embodiment.
FIG. 3 is a sectional side view taken along the line AA of FIG. 2;
FIG. 4 is an enlarged sectional side view showing a main part of the puncture mechanism of FIG. 3;
FIG. 5 is a partially cutaway front view similar to FIG. 2 and illustrating a pumping operation of a manual pump of the puncture device according to the first embodiment.
FIG. 6 is a partially cutaway front view similar to FIG. 2, illustrating a state in which an operation button of the puncture device is pressed to fire a puncture needle.
FIG. 7 is an enlarged sectional view taken along the line BB of FIG. 6;
FIG. 8 is an enlarged sectional side view showing a main part of the puncture mechanism of FIG. 7;
FIG. 9 is an enlarged cross-sectional view illustrating an automatic retraction operation of the puncture needle fired by the puncture device according to the first embodiment.
FIG. 10 is a cross-sectional front view showing, in an enlarged manner, a part of the operation button and the air suction passage of the manual pump that have been returned to the home positions of the puncture device.
11 is a cross-sectional front view similar to FIG. 10, illustrating a state when the operation button of FIG. 10 is operated from a fixed position to a firing position.
12 is a cross-sectional front view similar to FIG. 10, illustrating a state when the operation button of FIG. 11 is operated from a fixed position to an atmosphere release position.
FIG. 13 is a block diagram illustrating a control circuit of the puncturing apparatus.
[Explanation of symbols]
1 puncture device
2 First case
3 Second case
4. Monitor as display means
9 Puncture opening
11 Puncture mechanism
12 Chip which is a component sampling tool
13 Lancet as puncture means
14 puncture needle
15 Component detection unit as component detection means
23 Puncture axis
25 Launching Spring
26 Spring for rebound
32 Locking mechanism
37 Operation axis
38 Operation Buttons Combined with Launching Means and Atmospheric Release Means
55 Manual pump as manual decompression means
79 Pressure sensor as a means for detecting reduced pressure in puncturing opening
81 Control circuit
82 processing unit
83 component measurement section
85 Decompression notification section
93 Buzzer output part as notification means

Claims (6)

A puncturing mechanism that launches a puncturing means for forming a wound on the skin to exude body fluid into the puncturing opening,
Manual decompression means for manually depressurizing the inside of the puncturing opening,
A puncturing device, comprising: a notifying unit for notifying that at least the reduced pressure value in the puncturing opening by the manual pressure reducing unit has reached a predetermined value. 2. The puncture apparatus according to claim 1, further comprising an atmosphere opening means for opening the inside of the puncturing opening depressurized by the manual pressure reducing means to the atmosphere as needed. The puncturing apparatus according to claim 2, wherein the puncturing mechanism has a launching unit that launches the puncturing unit into the puncturing opening, and the launching unit also serves as the atmosphere opening unit. 2. The apparatus according to claim 1, further comprising: a component detecting unit configured to detect a component of a bodily fluid exuded into the puncturing opening by firing the puncturing unit to the puncturing opening to form a wound on the skin. A puncture device according to item 1. The puncturing apparatus according to claim 1, further comprising a monitor that displays a reduced pressure state in the puncturing opening by the manual pressure reducing unit. A first case in which a puncture opening is formed, and a puncture mechanism for emitting a puncture means into the puncture opening and forming a wound on the skin is accommodated;
A second case in which a manual decompression unit that decompresses the inside of the puncturing opening is accommodated, and a second case that operates the manual decompression unit by sliding with respect to the first case;
A puncture device, comprising: a monitor provided in the second case, the monitor displaying at least a decompression state in the puncture opening by the manual decompression means.

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